19.100 无损检测 标准查询与下载

LST EN ISO 3452-1:2021 无损检测 渗透检测 第1部分：一般原则（ISO 3452-1:2021）

Non-destructive testing - Penetrant testing - Part 1: General principles (ISO 3452-1:2021)

T/GAMA 21-2021 增材制造金属构件的离线检测 水浸超声法

规定了采用激光选区熔化和激光近净成型工艺技术的金属（包括钛合金、铝合金、不锈钢、高温合金、镍钛合金等）增材制造构件（以下 简称“受检件”）水浸超声离线检测方法的基本要求、检测设备、受检件、检测方法、质量等级、数据处理和检测记录及报告

Water immersion ultrasonic method for off-line inspection of additively manufactured metal components

SN EN ISO 3452-2:2021 无损检测 渗透检测 第2部分：渗透材料检测（ISO 3452-2:2021）

Non-destructive testing - Penetrant testing - Part 2: Testing of penetrant materials (ISO 3452-2:2021)

SN EN ISO 3452-1:2021 无损检测 渗透检测 第1部分：一般原则（ISO 3452-1:2021）

Non-destructive testing - Penetrant testing - Part 1: General principles (ISO 3452-1:2021)

T/CASEI 001-2021 特种设备无损检测机构级别评定准则

明确了特种设备无损检测机构级别评定双方的权力和义务，评定程序、内容、要求、评定参数，明确了监督检查要求等

Guidelines for rating special equipment non-destructive-test inspection agency

BS EN 12543-2:2021 非破坏性测试 用于无损检测的工业 X 射线系统中焦点的特性 针孔相机射线照相法

Non-destructive testing. Characteristics of focal spots in industrial X-ray systems for use in non-destructive testing. Pinhole camera radiographic method

GSO ISO 10880:2021 无损检测 红外热成像检测 一般原则

ISO 10880:2017 provides general principles for infrared thermographic testing in the field of industrial non-destructive testing (NDT).

Non-destructive testing — Infrared thermographic testing — General principles

GSO ISO 15708-3:2021 无损检测计算机断层扫描辐射方法 第3部分：操作和解释

ISO 15708-3:2017 presents an outline of the operation of a computed tomography (CT) system and the interpretation of results with the aim of providing the operator with technical information to enable the selection of suitable parameters. It is applicable to industrial imaging (i.e. non-medical applications) and gives a consistent set of CT performance parameter definitions, including how those performance parameters relate to CT system specifications. ISO 15708-3:2017 deals with computed axial tomography and excludes other types of tomography such as translational tomography and tomosynthesis.

Non-destructive testing — Radiation methods for computed tomography — Part 3: Operation and interpretation

GSO ISO/TR 13115:2021 无损检测 互易技术对声发射换能器进行绝对校准的方法

ISO/TR 13115:2011 describes the method of three-transducer calibration for calibrating frequency responses of absolute sensitivity by means of a reciprocity technique using three reversible acoustic emission transducers of the same kind, the method of two-transducer calibration for calibrating frequency responses of reception sensitivity of an optional acoustic emission transducer by using one acoustic emission transducer, the transmission responses of which have been calibrated by three-transducer calibration, the method for impulse response calibration for calibrating impulse responses of absolute sensitivity through inverse Fourier transform of the frequency responses measured by the three-transducer calibration, and the method for representing the calibration results.

Non-destructive testing — Methods for absolute calibration of acoustic emission transducers by the reciprocity technique

GSO ISO 18081:2021 无损检测 声发射测试 (AT) 通过声发射进行泄漏检测

ISO 18081:2016 specifies the general principles required for leak detection by acoustic emission testing (AT). It is addressed to the application of the methodology on structures and components, where a leak flow as a result of pressure differences appears and generates acoustic emission (AE). It describes phenomena of the AE generation and influence of the nature of fluids, shape of the gap, wave propagation and environment. The different application methods, instrumentation and presentation of AE results is discussed. Also included are guidelines for the preparation of application documents which describe specific requirements for the application of the AE method. Different application examples are given. Unless otherwise specified in the referencing documents, the minimum requirements of this International Standard are applicable.

Non-destructive testing — Acoustic emission testing (AT) — Leak detection by means of acoustic emission

GSO ISO 18563-2:2021 无损检测 超声相控阵设备的表征和验证 第2部分：探头

ISO 18563-2:2017 specifies the characterization tests performed at the end of the fabrication of a phased array probe. It defines both methodology and acceptance criteria. ISO 18563-2:2017 is applicable to the following phased array probes used for ultrasonic non-destructive testing in contact technique (with or without a wedge) or in immersion technique, with centre frequencies in the range 0,5 MHz to 10 MHz: a) non-matrix array probes: - linear; - encircling; - partial annular sectorial (type "daisy"); b) 2D-matrix array probes. ISO 18563-2:2017 does not give methods and acceptance criteria to characterize the performance of an ultrasonic phased array instrument or the performance of a combined system. These are given in ISO 18563?1 and in ISO 18563?3.

Non-destructive testing — Characterization and verification of ultrasonic phased array equipment — Part 2: Probes

ASTM E1220-21 用溶剂去除法进行可见渗透试验的标准实施规程

1.1?This practice2 covers procedures for visible penetrant examination utilizing the solvent-removable process. It is a nondestructive testing method for detecting discontinuities that are open to the surface such as cracks, seams, laps, cold shuts, laminations, isolated porosit

Standard Practice for Visible Penetrant Testing Using Solvent-Removable Process

GSO ISO 18211:2021 无损检测 使用轴向传播导波测试对地上管道和工厂管道进行远程检查

ISO 18211:2016 specifies a method for long-range testing of carbon and low-alloy steel above-ground pipelines and plant piping using guided ultrasonic waves with axial propagation applied on the entire circumferential pipe section, in order to detect corrosion or erosion damage. The guided wave testing (GWT) method allows for fast inspection of above-ground pipelines, plant piping and cased road crossings, giving a qualitative screening and localization of probable corroded and eroded areas. GWT is typically performed on operating piping systems. ISO 18211:2016 is applicable to the following types of pipes: a) above-ground painted pipelines; b) above-ground insulated pipelines; c) painted plant piping; d) insulated plant piping. NOTE Pipe sections within road crossings with external casings (without bitumen or plastic coating) are a special case of buried pipe where there is no soil pressure on the OD of the pipe. ISO 18211 :2016 applies to these cased road crossings. Other types of pipes not included in the above list need dedicated approaches due to increased complexity.

Non-destructive testing — Long-range inspection of above-ground pipelines and plant piping using guided wave testing with axial propagation

OENORM EN 12543-2-2021 无损检测 用于无损检测的工业 X 射线系统中焦点的特征 第2部分：针孔照相机射线照相方法

Non-destructive testing - Characteristics of focal spots in industrial X-ray systems for use in non-destructive testing - Part 2: Pinhole camera radiographic method

GSO ISO 15708-4:2021 无损检测 计算机断层扫描辐射方法 第4部分：资格

ISO 15708-4:2017 specifies guidelines for the qualification of the performance of a CT system with respect to various inspection tasks. It is applicable to industrial imaging (i.e. non-medical applications) and gives a consistent set of CT performance parameter definitions, including how those performance parameters relate to CT system specifications. ISO 15708-4:2017 deals with computed axial tomography and excludes other types of tomography such as translational tomography and tomosynthesis.

Non-destructive testing — Radiation methods for computed tomography — Part 4: Qualification

ASTM E1219-21 用溶剂去除法进行荧光液体渗透试验的标准实施规程

1.1 This practice2 covers procedures for fluorescent penetrant examination utilizing the solvent-removable process. It is a nondestructive testing method for detecting discontinuities that are open to the surface, such as cracks, seams, laps, cold shuts, laminations, isolated porosity, through leaks, or lack of fusion and is applicable to in-process, final, and maintenance examination. It can be effectively used in the examination of nonporous, metallic materials, both ferrous and nonferrous, and of nonmetallic materials such as glazed or fully densified ceramics and certain nonporous plastics and glass. 1.2 This practice also provides a reference: 1.2.1 By which a fluorescent penetrant examination solventremovable process recommended or required by individual organizations can be reviewed to ascertain its applicability and completeness. 1.2.2 For use in the preparation of process specifications dealing with the fluorescent solvent-removable liquid penetrant examination of materials and parts. Agreement by the purchaser and the manufacturer regarding specific techniques is strongly recommended. 1.2.3 For use in the organization of the facilities and personnel concerned with the liquid penetrant examination. 1.3 This practice does not indicate or suggest standards for evaluation of the indications obtained. It should be pointed out, however, that indications must be interpreted or classified and then evaluated. For this purpose there must be a separate code or specification or a specific agreement to define the type, size, location, and direction of indications considered acceptable, and those considered unacceptable. 1.3.1 The user is encouraged to use materials and processing parameters necessary to detect conditions of a type or severity which could affect the evaluation of the product. 1.4 All areas of this document may be open to agreement between the cognizant engineering organization and the supplier, or specific direction from the cognizant engineering organization. 1.5 Units—The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered standard. 1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

Standard Practice for Fluorescent Liquid Penetrant Testing Using the Solvent-Removable Process

GSO ISO 19675:2021 无损检测 超声波检测 相控阵测试（PAUT）校准块规范

ISO 19675:2017 specifies requirements for the dimensions, material and manufacture of a steel block for calibrating ultrasonic test equipment used in ultrasonic testing with the phased array technique.

Non-destructive testing — Ultrasonic testing — Specification for a calibration block for phased array testing (PAUT)

GSO ISO 18249:2021 无损检测 声发射检测 纤维增强聚合物检测的具体方法和一般评价标准

ISO 18249:2015 describes the general principles of acoustic emission testing (AT) of materials, components, and structures made of fibre-reinforced polymers (FRP) with the aim of - materials characterization, - proof testing and manufacturing quality control, - retesting and in-service testing, and - health monitoring. This International Standard has been designed to describe specific methodology to assess the integrity of fibre-reinforced polymers (FRP), components, or structures or to identify critical zones of high damage accumulation or damage growth under load (e.g. suitable instrumentation, typical sensor arrangements, and location procedures). It also describes available, generally applicable evaluation criteria for AT of FRP and outlines procedures for establishing such evaluation criteria in case they are lacking. ISO 18249:2015 also presents formats for the presentation of acoustic emission test data that allows the application of qualitative evaluation criteria, both online during testing and by post-test analysis, and that simplify comparison of acoustic emission test results obtained from different test sites and organizations. NOTE The structural significance of the acoustic emission cannot in all cases definitely be assessed based on AT evaluation criteria only but can require further testing and assessment (e.g. with other non-destructive test methods or fracture mechanics calculations).

Non-destructive testing — Acoustic emission testing — Specific methodology and general evaluation criteria for testing of fibre-reinforced polymers

GSO ISO 18251-1:2021 无损检测红外热成像 第1部分：系统和设备的特性

ISO 18251-1:2017 describes the main components, and their characteristics, constituting an infrared (IR) imaging system and related equipment used in non-destructive testing (NDT). It also aims to assist the user in the selection of an appropriate system for a particular measurement task. The following items are specified: - objective lens; - detector; - image processor; - display; - thermal stimulation source; - accessories.

Non-destructive testing — Infrared thermography — Part 1: Characteristics of system and equipment

GSO ISO 20669:2021 无损检测 铁磁金属部件的脉冲涡流检测

ISO 20669:2017 specifies the pulsed eddy current (PEC) testing technique used to perform thickness measurement on ferromagnetic metallic components with or without the presence of coating, insulation and weather sheeting. ISO 20669:2017 applies to the testing of in-service components made of carbon steel and low-alloy steel in the temperature of −100 °C to 500 °C (temperature measured at metal surface). The range of wall thickness of components is from 3 mm to 65 mm and the range of thickness of coatings is from 0 mm to 200 mm. The tested components also include piping of diameter not less than 50 mm. The technique described in this document is sensitive to the geometry of the component and applying the technique to components outside of its scope will result in unpredictable inaccuracy. This document does not apply to the testing of crack defects and local metal loss caused by pitting. ISO 20669:2017 does not establish evaluation criteria. The evaluation criteria shall be specified by the contractual agreement between parties.

Non-destructive testing — Pulsed eddy current testing of ferromagnetic metallic components